CN107152908A - Splice on-line measuring device and detection method in tower type solar energy thermal power generation heliostat monolithic devices face - Google Patents
Splice on-line measuring device and detection method in tower type solar energy thermal power generation heliostat monolithic devices face Download PDFInfo
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- CN107152908A CN107152908A CN201710416894.6A CN201710416894A CN107152908A CN 107152908 A CN107152908 A CN 107152908A CN 201710416894 A CN201710416894 A CN 201710416894A CN 107152908 A CN107152908 A CN 107152908A
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01B—MEASURING LENGTH, THICKNESS OR SIMILAR LINEAR DIMENSIONS; MEASURING ANGLES; MEASURING AREAS; MEASURING IRREGULARITIES OF SURFACES OR CONTOURS
- G01B7/00—Measuring arrangements characterised by the use of electric or magnetic techniques
- G01B7/28—Measuring arrangements characterised by the use of electric or magnetic techniques for measuring contours or curvatures
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Abstract
The invention provides tower type solar energy thermal power generation heliostat monolithic devices face splicing on-line measuring device and detection method, detection means is made up of lattice supporting framework, truss fixed structure and displacement transducer, lattice supporting framework is fixed on ground runners in couples, truss fixed structure is across the top in a pair of lattice supporting frameworks, truss fixed structure two ends bottom forms one group of gantry frame structure with being fixedly connected at the top of lattice supporting framework;Displacement transducer is vertically installed at truss fixed structure both sides in couples, and every two pairs of displacement transducers are one group, and multigroup displacement transducer is horizontally installed with each truss fixed structure;The detection means is made up of multigroup gantry frame structure longitudinal arrangement.The detection method detects the setting height(from bottom) of tested heliostat by detection means, and it is adjusted, ensure heliostat installation accuracy in theoretical error range, and then meet heliostat monolithic devices face splicing on-line checking during, side install adjust frontier inspection survey demand.
Description
Technical field
The invention belongs to solar energy thermal-power-generating light concentrator type face detection technique field, and in particular to a kind of tower-type solar thermal
Splice on-line measuring device and detection method in power generation settled date mirror monolithic devices face.
Background technology
Tower type solar energy thermal power generation technology belongs to renewable energy utilization technology, has obtained hair quickly in China in recent years
Exhibition, and commercialization is done step-by-step.Tower type solar energy thermal power generation technology assembles solar radiation to tower top heat dump using heliostat field,
Heat energy is obtained by heat dump and the heat to power output system on ground is delivered to, electric energy is finally produced.
Tower type solar energy thermal power generation is main by heliostat condensing system, heat absorption and thermal energy transfer systems, electricity generation system three
It is grouped into.Heliostat is the core component in tower type solar energy thermal power generation station, and its universal architecture is by numerous planes or slightly concave
Speculum is spliced to form overall a sphere or parabolic concentrator, and by solar radiation reflecting focal to heat dump, heliostat
Monolithic devices face precision determine the generating efficiency at tower type solar energy thermal power generation station, realize the efficient photothermal deformation of condenser system
It is crucial, it is therefore desirable to which that heliostat monolithic devices face is accurately detected.
At present, the detection method in heliostat monolithic devices face mainly has laser beam projection scanning method, striped grid Morie fringe
Detection method, target bounce technique etc..
Laser beam projection scanning method is that laser beam passes through spectroscope and multiple prisms, is projected on sub- mirror minute surface to be measured, then
By sub- mirror and prismatic reflection, last spectroscope projection is converged on position sensor, is thrown by comparing the theoretical of reflection light
Position is penetrated, the Norma l deviation of each sub- mirror is determined, this method is longer, less efficient to the detection time in settled date mirror-type face, and cost
It is higher.
Striped grid Morie fringe detection method is to shoot striped through tested condenser reflection imaging, grid using camera
The picture of striped carries the modulation intelligence of tested condenser, and image procossing, and then inverting condenser are carried out to the picture of grid striped
The normal direction information of each sub- mirror central point, this method be it is a kind of can realize quick high accuracy detection good method, but device into
This higher and follow-up image procossing is complex.
Target bounce technique is first to make special target, shoots target through heliostat imaging using camera, compares target through ideal
Heliostat into picture, and then determine each sub- mirror Central Point Method to deviation information, this method is a kind of quick, efficient detection to can be achieved
Method, but high is required to the making of target, measuring accuracy is relatively low.
Although the above method can be detected to heliostat monolithic devices face, heliostat can not be met in splicing mistake
Detected in journey, i.e., the demand of frontier inspection survey is debug on side.To meet the extensive foundation of tower type solar thermo-power station, in the urgent need to
A kind of detection means and method efficient, quick, accurate and that be capable of the splicing of on-line checking heliostat monolithic devices face.
The content of the invention
The present invention detects that the cumbersome time is longer, efficiency is low, inspection to solve to exist during existing Surface inspection overall to heliostat
Survey that cost is higher, it is quick to be not suitable for, on-line checking the problems such as there is provided a kind of spelling of tower type solar energy thermal power generation heliostat monolithic devices face
It is connected on line detector and detection method.With reference to Figure of description, technical scheme is as follows:
On-line measuring device is spliced in tower type solar energy thermal power generation heliostat monolithic devices face, and the detection means is by truss support
Structure 1, truss fixed structure 2 and displacement transducer 3 are constituted, and the lattice supporting framework 1 is fixed on ground runners in couples,
The truss fixed structure 2 is across the top in a pair of lattice supporting frameworks 1, the two ends bottom of truss fixed structure 2 and purlin
The top of frame support structure 1 is fixedly connected, and forms one group of gantry frame structure;
Institute's displacement sensors 3 are vertically installed at the both sides of truss fixed structure 2 in couples, and every two pairs of displacement transducers 3 are
One group, multigroup displacement transducer 3 is horizontally installed with each truss fixed structure 2;
The detection means is made up of multigroup gantry frame structure longitudinal arrangement.
The lattice supporting framework 1 is by truss lower carrier plate 101, ribs I 102, truss upright-column 103, the and of ribs II 104
Truss upper supporting plate 105 is constituted;
The truss upright-column 103 is fixed by truss lower carrier plate 101 with ground runners, and the truss upper supporting plate 105 is fixed
At the top of truss upright-column 103, and it is connected with truss fixed structure 2, ribs I 102 is welded on truss upright-column 103 with being propped up under truss
Between plate 101, the ribs II 104 is welded between truss upright-column 103 and truss upper supporting plate 105.
The truss fixed structure 2 is connected by truss crossbeam 201, crossbeam pinboard 202, fixed support frame 203 and sensor
Fishplate bar 204 is constituted.The truss crossbeam 201 is the cuboid framework being welded by shaped steel, two crossbeam pinboards 202
Symmetrically fixed at the bottom surface two ends of truss crossbeam 201, the crossbeam pinboard 202 is connected with lattice supporting framework 1, the sensor
Connecting plate 204 is installed on the side of truss crossbeam 201, the sensor connecting plate 204 and displacement by the fixed support frame 203
Sensor 3 is connected.
Institute's displacement sensors 3 are by the bottom plate 301 that is connected, the plate I 302 that is connected, guide rail end cap 303, magnetic railings ruler
304th, line slideway 305, magnetic grid ruler reading head 306, slide attachment plate 307, probe fixed block 308, the upper plate 309 that is connected,
Spindle motor 310, the plate II 311 that is connected, screw connecting plate 313, probe 315, leading screw lower end fixed block 318, linear bearing I
319 and probe baffle plate 322 constitute;
The bottom plate 301 that is connected, the plate I 302 that is connected, be connected upper plate 309 and be connected plate II 311 according to
The cuboid of secondary right angle setting composition closing;
The line slideway 305 is fixed on the inner side of plate I 302 that is connected, and the guide rail end cap 303 is fixedly mounted on straight line
The two ends of guide rail 305, the magnetic railings ruler 304 be arranged in parallel with line slideway 305 and installed in being connected on plate I 302, described to visit
Pin fixed block 308 is connected by slide attachment plate 307 with the sliding block of line slideway 305, and the magnetic grid ruler reading head 306 is arranged on
The side of slide attachment plate 307 simultaneously matches with magnetic railings ruler 304;
The probe 315 is connected to the lower section of probe fixed block 308 vertically, and the spindle motor 310 is vertically installed at connection
On fixed upper plate 309, the probe fixed block 308 is connected by screw connecting plate 313 with the screw of spindle motor 310, leading screw
Lower end fixed block 318 is fixed on the leading screw end of spindle motor 310, coordinates with leading screw tip gap;
The linear bearing I 319 is arranged on being connected on bottom plate 301 immediately below probe 315, the probe baffle plate
322 are slidably mounted on the upper surface of probe baffle plate 322 and company at the bottom of bottom plate 301 that is connected, and the axis hole of linear bearing I 319
The upper surface for connecing fixed bottom plate 301 is coplanar.
Further, institute's displacement sensors 3 also include linear bearing II 312, the axis of guide 314 and axis of guide fixed block
317;
The axis of guide 314 is arranged on the leading screw both sides of spindle motor 310, the straight line by axis of guide fixed block 317
Bearing II 312 is slidably connected on the axis of guide 314, and is connected with screw connecting plate 313.
Further, institute's displacement sensors 3 also include the free end-stopping plate for being fixed on the bottom surface of bottom plate 301 that is connected
320 are slidably mounted in free end-stopping plate 320 and fixed end-stopping plate 321 with fixed end-stopping plate 321, the probe baffle plate 322
In groove, when pushing the probe baffle plate 22 in the fixed groove of end-stopping plate 21 to free end-stopping plate 20, probe baffle plate 22 is by linear bearing I 19
Axis hole block, when probe baffle plate 22 is forced back towards in the fixed groove of end-stopping plate 21, the axis hole of linear bearing I 19 is exposed.
Further, the leading screw of the spindle motor 310 is trapezoidal screw.
Online test method is spliced in tower type solar energy thermal power generation heliostat monolithic devices face, and the detection method detailed process is such as
Under:
Installation site between S1, adjustment lattice supporting framework 1, truss fixed structure 2 and displacement transducer 3 is right in advance
The initial position for having completed the probe 315 in the displacement transducer 3 of adjustment is demarcated, and is determined to be measured by orbital path
Solar eyepiece 4 is transported at the position directly below of detection means;
The initial position of the probe 315 is:When the lower surface of the end of probe 315 and the bottom plate 301 that is connected is coplanar
Position;
S2, power-on, descending vertically by the driving screw of electric control system controls spindle motor 310, probe 315 is erected therewith
Directly move downward, and it is vertical descending through the bottom plate 301 that is connected, when the end of probe 315 is touched on corresponding heliostat 4
During surface, probe 315 will stop moving downward, and now the screw of spindle motor 310 runs at lower limit position and stopped;
When S3, the heliostat 4 being measured by the acquisition contact of probe 315 of magnetic grid ruler reading head 306, probe 315, which stretches out, to be connected
The length of the fixed lower surface of bottom plate 301 is connect, and the extension elongation of probe 315 is shown in real time in the form of numerical value over the display
Show, by the setting height(from bottom) of the tested heliostat 4 of adjustment, and observe the real-time numerical value of display, it is ensured that the installation accuracy of heliostat 4
In theoretical error range, so meet the monolithic devices face of heliostat 4 splicing on-line checking during, side install adjust frontier inspection survey
Demand;
When S4, the installation of the heliostat 4 and adjustment reach theory calls, then detection is completed, and then passes through electric-control system
Control spindle motor 310 to drive screw up vertically, stop when screw drives probe 315 to run at upper extreme position, treat
After whole probes 315 in detection means are moved at upper extreme position, it will detect that the heliostat 4 completed is defeated by orbital path
Designated area is sent to, then next group of heliostat 4 to be measured is transported at the position directly below of detection means debug, in repetition
State step S2, S3 and complete the monolithic devices face of heliostat 4 splicing on-line checking process.
Compared with prior art, the beneficial effects of the present invention are:
1st, it is of the present invention to survey in device using the equidistant longitudinally mounted formation of five groups of separate gantry frame structures
Detecting system, is measured, the device greatly enhances the settled date while can meeting a large amount of settled date mirror unit mirror splice type faces
The detection efficiency in mirror monolithic devices face;
2nd, displacement transducer of the present invention that used in device of surveying can not only realize the measurement of wide range, meet actual
Use demand, and higher measurement accuracy can be obtained, displacement transducer is moved up and down vertically using spindle motor as probe
Driving source, make displacement transducer realize automatic measurement and with Self-resetting measurement function;
3rd, survey device of the present invention possesses unified testing process, simple to operate, shortens detection time, improves
Detection efficiency, detection method of the present invention is relatively reasonable, it is ensured that measurement accuracy, reduces testing cost, and it is fixed to be adapted to
Solar eyepiece monolithic devices face is quick, on-line checking demand.
Brief description of the drawings
Fig. 1 is that the structure of tower type solar energy thermal power generation heliostat monolithic devices face of the present invention splicing on-line measuring device is shown
It is intended to;
Fig. 2 be detection means of the present invention in, the schematic diagram of lattice supporting framework;
Fig. 3 be detection means of the present invention in, the schematic diagram of truss fixed structure;
Fig. 4 be detection means of the present invention in, the overall structure diagram of displacement transducer;
Fig. 5 be detection means of the present invention in, the polycrystalline substance schematic diagram of displacement transducer;
In figure:
1 lattice supporting framework, 2 truss fixed structures, 3 displacement transducers, 4 heliostats;
101 truss lower carrier plates, 102 ribs I, 103 truss upright-columns, 104 ribs II,
105 truss upper supporting plates;
201 truss crossbeams, 202 crossbeam pinboards, 203 fixed support frames, 204 sensor connecting plates;
301 are connected bottom plate, and 302 are connected plate I, 303 guide rail end caps, 304 magnetic railings rulers,
305 line slideways, 306 magnetic grid ruler reading heads, 307 slide attachment plates, 308 probe fixed blocks,
309 are connected upper plate, 310 spindle motors, and 311 are connected plate II, 312 linear bearings II,
313 screw connecting plates, 314 axis of guides, 315 probes, 316 springs,
317 axis of guide fixed blocks, 318 leading screw lower end fixed blocks, 319 linear bearings I, 320 free end-stopping plates,
321 fix end-stopping plate, 322 probe baffle plates.
Embodiment
For technical scheme is expanded on further, with reference to Figure of description, embodiment of the invention is as follows:
As shown in figure 1, splicing on-line checking the invention provides a kind of tower type solar energy thermal power generation heliostat monolithic devices face
Device, the detection means is made up of lattice supporting framework 1, truss fixed structure 2 and displacement transducer 3, the truss support knot
Structure 1 is transversely bolted on ground runners by truss lower carrier plate 101 in couples, and the lattice supporting framework 1 is on ground
On footing seat there is vertical linear to adjust function;The truss fixed structure 2 is transversely arranged on a pair of lattice supporting frameworks 1
Top, the truss fixed structure 2 passes through on the crossbeam pinboard 202 of two ends bottom and the truss at the top of lattice supporting framework 1
The bolt of support plate 105 is fixedly connected, and the truss fixed structure 2 and a pair of lattice supporting frameworks 1 are connected to form one group of gantry
Frame structure, and the truss fixed structure 2 has vertical and horizontal Serial regulation function on lattice supporting framework 1;Institute's rheme
Displacement sensor 3 is vertically installed at the sensor connecting plate 204 of the both sides of truss fixed structure 2 by the plate 302 that is connected in couples
On, and be bolted, and institute's displacement sensors 3 have horizontal linear adjustment function and vertical on truss fixed structure 2
Adjustment function (is swung) i.e. in vertical plane to rotation, the vertical peace of displacement transducer 3 can be achieved by the adjustment of each free degree
Dress.
In the present embodiment, the detection means is made up of five groups of structure identical gantry frame structures, and every group of portal frame knot
Structure is equally spacedly arranged in parallel along longitudinal direction, in each group of gantry frame structure, and every two pairs of displacement transducers 3 are one group, have seven
Group displacement transducer is equally spacedly linearly mounted to the both sides of the truss fixed structure 2, i.e., in this detection means, institute's rheme
Displacement sensor 3 has 35 groups, is distributed in the column matrix formula of 5 rows × 7, every group of displacement transducer 3 is by four symmetrical group of displacement transducers 3
Into;Heliostat 4 to be detected by a series of horizontal and vertical equidistant unit microscope groups into, in the present embodiment, the settled date
Mirror 4 is transversely equidistantly rearranged by the unit mirror of seven face rectangular strips, the unit mirror be located at displacement transducer 3 just under
Side, five groups of displacement transducers 3 of correspondence per face unit mirror, five groups of displacement transducers 3 are in the column distribution of 5 rows × 1;Every group of position
Displacement sensor 3 is measured to the setting height(from bottom) of corresponding unit mirror, the spy of the internal probe 315 of institute's displacement sensors 3
Location puts the position of four index points as unit mirror, realizes and measures display to the setting height(from bottom) of every face unit mirror, and
Setting height(from bottom) to unit mirror is adjusted, to ensure the installation accuracy of every face unit mirror in theoretical error range, so that real
The on-line checking in the existing monolithic devices face of heliostat 4.
As shown in Fig. 2 the lattice supporting framework 1 by truss lower carrier plate 101, ribs I 102, truss upright-column 103, plus
Strong rib II 104 and truss upper supporting plate 105 are constituted.The truss lower carrier plate 101 is fixed by bolt with ground runners, and the purlin
Four bolts hole at the edge of frame lower carrier plate 101 are longitudinal strip hole, to realize the position on ground runners of lattice supporting framework 1
Vertical linear is adjusted;The truss upper supporting plate 105 is parallel with truss lower carrier plate 101 to be correspondingly arranged, the side of truss upper supporting plate 105
Edge has four longitudinal strip mounting holes, realizes that vertical linear when being installed with truss fixed structure 2 is adjusted;The truss upright-column
103 be hollow section, and truss upright-column 103 is fixed between the middle part of truss upper supporting plate 105 and the middle part of truss lower carrier plate 101 vertically;
The ribs I 102 is welded between truss upright-column 103 and truss lower carrier plate 101, and the ribs I 102 is right-angled trapezium,
One right-angle side is welded and fixed with truss lower carrier plate 101, and another right-angle side is welded and fixed with the outer surface lower end of truss upright-column 103,
The each outer surface lower end of truss upright-column 103 is symmetrically welded two ribs I 102, described 103 4 outer surfaces of truss upright-column
Lower end is welded and fixed by eight ribs I 102, to ensure its stability of strutting system;The ribs II 104 is also right-angled trapezium,
One right-angle side is welded and fixed with truss upper supporting plate 105, and the outer surface upper end welding of another right-angle side and truss upright-column 103 is solid
Fixed, each outer surface upper end of truss upright-column 103 is symmetrically welded two ribs II 104, and the truss upright-column 103 4 is outer
Side surface upper end is welded and fixed by eight ribs II 104, to ensure its support strength.
As shown in figure 3, the truss fixed structure 2 is by truss crossbeam 201, crossbeam pinboard 202, fixed support frame 203
Constituted with sensor connecting plate 204.The truss crossbeam 201 is the line style framework being welded by shaped steel, the end of truss crossbeam 201
Rectangular cross-section, is that displacement transducer 3 provides space mounting position, two crossbeam pinboards 202 are at the bottom of truss crossbeam 201
Face two ends are symmetrically welded, and there are four horizontal strip holes, four with the edge of truss upper supporting plate 105 in the edge of crossbeam pinboard 202
Individual longitudinal strip hole is vertically matched, composition " ten " word groove profile hole, to realize longitudinal direction and the horizontal stroke to the installation site of truss fixed structure 2
To Serial regulation;The side of the fixed support frame 203 is installed on the side of truss crossbeam 201, and is bolted fixation, and
The mounting hole of fixed support frame 203 and the installation place of truss crossbeam 201 is vertical strip hole, makes fixed support frame 203 in installation position
The place of putting can realize that vertical linearity is adjusted, and meet the reasonability of the locus of displacement transducer 3;The sensor connecting plate 204 with
The opposite side of fixed support frame 203 is bolted, and junction one end is circular bolt holes, and the other end is arcuate socket, with reality
The existing transverse rotation of displacement transducer 3 adjustment (adjustment is swung i.e. in vertical plane), to ensure that displacement transducer 3 is vertically-mounted.One
One link of the individual fixed support frame 203 and a corresponding connection composition of sensor connecting plate 204, the link
Truss crossbeam 201 is connected to for displacement transducer 3 to be installed, as it was previously stated, relative with the installation site of displacement transducer 3
Ying Di, every four links are one group, and each group link is equidistantly installed along truss crossbeam 201.
As shown in Figure 4 and Figure 5, institute's displacement sensors 3 use line slideway 305 as linear movement unit, using silk
Thick stick motor 310 is as linear drive unit, and using magnetic railings ruler 304 as displacement measurement unit, linear drive unit is by automatically controlled reality
The probe 315 for now driving linear moving cell to carry has a vertically movable free degree, and the vertically movable displacement of probe 315 can be by
Displacement measurement unit is acquired and shown in display with numeric form, by showing peace of the numerical value to the unit mirror of heliostat 4
Dress height, which is adjusted, ensures the installation accuracy per face unit mirror in theoretical error range, so as to realize the monolithic devices of heliostat 4
The on-line checking in face.The concrete composition and annexation of displacement transducer 3 are as follows:
Institute's displacement sensors 3 are by the bottom plate 301 that is connected, the plate I 302 that is connected, guide rail end cap 303, magnetic railings ruler
304th, line slideway 305, magnetic grid ruler reading head 306, slide attachment plate 307, probe fixed block 308, the upper plate 309 that is connected,
Spindle motor 310, the plate II 311 that is connected, linear bearing II 312, screw connecting plate 313, the axis of guide 314, probe 315, bullet
Spring 316, axis of guide fixed block 317, leading screw lower end fixed block 318, linear bearing I 319, free end-stopping plate 320, fixed end-stopping plate
321 and probe baffle plate 322 constitute.
The bottom plate 301 that is connected, the plate I 302 that is connected, be connected upper plate 309 and be connected plate II 311 according to
The cuboid framework of secondary vertical connection composition institute displacement sensors 3, wherein, plate I 302 and the plate that is connected of being connected
II 311 or so parallel installations, be connected bottom plate 301 and the upper plate parallel installation, the plate that is connected about 309 that be connected
I 302 and the two ends of plate II 311 that are connected respectively with being connected bottom plate 301 and the upper plate 309 that is connected is bolted,
And the connecting hole being connected between plate I 302 and the bottom plate 301 that is connected, the upper plate 309 that is connected is strip hole,
Make to be connected plate I 302 and the bottom plate 301 that is connected, the connection position that is connected between plate I 302 and the upper plate 309 that is connected
Put linear along its length adjustable.Plate I 302 and the sensor connecting plate in the truss fixed structure 2 of being connected
204 bolt connections, the plate I 302 that is connected is coordinated by the connection with sensor connecting plate 204, realizes the horizontal line of displacement transducer 3
Property adjustment and transverse rotation adjustment (i.e. in vertical plane swing adjustment), be arranged on truss fixed knot to meet displacement transducer 3
The 2-in-1 suitable position of structure.
The inner side centre position of plate 302 that is connected vertically is provided with line slideway stopper slot, and the straight line is led
Rail 305 is arranged in the line slideway stopper slot and fixed by bolt with the plate 302 that is connected, and realizes to line slideway
305 installation sites carry out mechanical position limitation, and the two ends of the line slideway 305 are provided with guide rail end cap 303 to prevent line slideway
Sliding block on 305 is slid from line slideway 305, and the guide rail end cap 303 is bolted with the plate 302 that is connected;Institute
The side for stating line slideway stopper slot is also provided with magnetic railings ruler stopper slot, the stickum that the magnetic railings ruler 304 passes through itself back
It is bonded and fixed in the magnetic railings ruler stopper slot, realizes and mechanical position limitation is carried out to the installation site of magnetic railings ruler 304, in addition, the magnetic
The two ends of grid chi 304 are also bolted with the plate 302 that is connected, and are lost with preventing the stickum at the back of magnetic railings ruler 304 to be bonded
Imitate and come off.
Connected between the side of the probe fixed block 308 and the sliding block of line slideway 305 by slide attachment plate 307,
The sliding block of the slide attachment plate 307 and line slideway 305 is bolted, and the probe fixed block 308 is connected with sliding block
Plate 307 is bolted, and probe fixed block 308 has the Serial regulation function of length direction on slide attachment plate 307,
So that the sliding block of probe fixed block 308 and line slideway 305 has suitable link position;The probe fixed block 308 it is another
Side is fixedly connected with by screw connecting plate 313, and the probe fixed block 308 is by the free support of screw connecting plate 313, and probe is solid
Determine block 308 to be synchronized with the movement with the screw of spindle motor 310;The side of the magnetic grid ruler reading head 306 and slide attachment plate 307 leads to
Bolt connection is crossed and with position regulating function, so that the sensitive face for meeting magnetic grid ruler reading head 306 is parallel and covering magnetic railings ruler 304
Surface, and the sensitive face of magnetic grid ruler reading head 306 and the surface spacing of magnetic railings ruler 304 ensure in 1mm or so, to ensure magnetic grid
Ruler reading head 306 recognizes the displacement pulse signals of magnetic railings ruler 304.
The flange of the spindle motor 310 is bolted with the upper plate 309 that is connected, the spindle motor 310 with
The leading screw Driven by Coaxial connection of lower end, end and the circular trough gap on leading screw lower end fixed block 318 of leading screw coordinate;The silk
Thick stick and the opposing parallel setting of line slideway 305.
The axis of guide 314 has two, parallel and be symmetrically disposed in leading screw both sides, and the linear bearing II 312 is installed
On the axis of guide 314, and the linear bearing II 312 of both sides is bolted with the screw connecting plate 313 positioned at centre, and two
Individual linear bearing II 312 is symmetrically installed on the both sides of screw connecting plate 313, and two linear bearings II 312 are led corresponding respectively
Linear movement is done on to axle 314, the screw of the leading screw is arranged in the U-type groove of the screw connecting plate 313, and the screw connects
The U-type groove of fishplate bar 313 and the crest clearance of screw coordinate, and the flange of the screw connecting plate 313 and screw is solid by bolt
Fixed connection;Leading screw lower end fixed block 318 is bolted on the lower end of plate II 311 that is connected, to spindle motor 310
Leading screw end carries out spacing, it is ensured that the process of screw motion is not fallen off;The axis of guide 314 is optical axis, and the axis of guide
The end face center at 314 two ends is machined with internal thread, and the two ends of the axis of guide 314 are separately installed with axis of guide fixed block 317, described to be oriented to
Axle fixed block 317 is L-type, and one side of axis of guide fixed block 317, which is fixedly connected on, to be connected on plate II 311, the axis of guide
314 another side and the end of the axis of guide 314 are bolted, and two axis of guide fixed blocks 317 are one group, are accordingly fixed
A piece axis of guide 314, two groups of axis of guide fixed blocks 317 are symmetrically installed and fixed two axis of guides being connected on plate II 311
314, the rotary motion to ensure spindle motor 310 switchs to the linear motion of screw, it is ensured that balance of the screw in motion process
It is stable, and then drive the probe fixed block 308 of the other end of screw connecting plate 313 to drive the motion of the vertical straight line of probe 315.
The probe 315 be arranged in parallel with leading screw, and one end of probe 315 is plane, and the other end of probe 315 is sphere,
Plane one end of probe 315 is arranged in the fixing hole of the bottom of probe fixed block 308, and probe 315 is fixed on probe by jackscrew
In fixed block 308, sphere one end of probe 315 faces the axle center for the linear bearing I 319 being connected on bottom plate 301, and energy
Enough through linear bearing I 319;The spring 316 is sleeved on probe 315 and is movably arranged in linear bearing I 319, described
The internal diameter of spring 316 is more than the diameter of axle of probe 315, and the external diameter of spring 316 is less than the external diameter of linear bearing I 319, the spring 316
Effect be the active force for mitigating the load of the top shoe of line slideway 305 to being tested minute surface, to reach the effect of the tested minute surface of protection
Really.
The linear bearing I 319 is bolted with the bottom plate 301 that is connected, and the flange of linear bearing I 319 is embedded into
Be connected bottom plate 301 lower surface groove in, sink to the surface of the flange of linear bearing I 319 and be connected under bottom plate 301
Surface certain distance;The free end-stopping plate 320 and fixed end-stopping plate 321 are arranged on the bottom plate 301 that is connected by bolt
Lower surface, and free end-stopping plate 320 and the fixed inner side of end-stopping plate 321 are equipped with the rectangular channel of supporting probe baffle plate 322, described
Probe baffle plate 322 is slidably mounted in the rectangular channel in free end-stopping plate 320 and fixed end-stopping plate 321, and probe baffle plate 322
Upper surface and the lower surface for the bottom plate 301 that is connected are coplanar;When need to be to the position of probe 315 (i.e. to the sphere end of probe 315
The coplanar position with the lower surface for the bottom plate 301 that is connected) when being demarcated, by the probe in the fixed rectangular channel of end-stopping plate 321
Baffle plate 322 pushes free end-stopping plate 320 to, the one end of probe baffle plate 322 is supported on the other end in the groove of fixed end-stopping plate 321 and supports
In the groove of free end-stopping plate 320, the axis hole of linear bearing I 319 is just blocked in the upper surface of probe baffle plate 322;When without right
During the location position of probe 315, probe baffle plate 322 is pushed back in the rectangular channel of fixed end-stopping plate 321, by fixed end-stopping plate 321
Rectangular channel two ends are supported, and the axis hole of linear bearing I 319 is exposed, and probe 315 can be passed freely through.
When institute's displacement sensors 3 measure work, the downward vertical linearity of screw is driven to move by spindle motor 310,
So as to drive probe 315 to move straight down, now probe baffle plate 322 is slid into the rectangular channel of fixed end-stopping plate 321, straight line
The axis hole of bearing I 319 is exposed, when the bulb end of probe 315 passes through linear bearing I 319, when touching measured lens surface no longer to
Lower motion, and the screw of spindle motor 310 is now also moved at lower limit position and stopped, and installed on slide attachment plate 307
Magnetic grid ruler reading head 306 with probe 315 to do identical vertically movable, by magnetic grid ruler reading head 306 on magnetic railings ruler 304
When vertically movable displacement can obtain the contact measured lens of probe 315, the length that probe 315 is stretched out can be right by spindle motor 310
The vertically movable speed of probe 315 is adjusted, and remains to reach the protection effect to measured lens in the case where meeting measurement efficiency
Really;After displacement transducer 3 completes to measure, drive the upward vertical linearity of screw to move by spindle motor 310, then drive probe
315 move straight up, stop until the screw of spindle motor 310 is moved at upper extreme position, now probe fixed block 308
Probe 315 is driven to return to topmost and supported by screw connecting plate 313, it is big that high accuracy can be achieved by the interaction of each component
The effect of range Self-resetting probe-type displacement measurement.
The leading screw is trapezoidal screw, in a non-operative state, and electric control system controls spindle motor 310 drives screw operation
To at upper extreme position, close after electric-control system, because trapezoidal screw self-locking performance is preferable, it is ensured that probe 315 is connected in screw
It will not fall in the presence of plate 313.
Splice the concrete structure of on-line measuring device, this hair with reference to above-mentioned tower type solar energy thermal power generation heliostat monolithic devices face
Bright to additionally provide a kind of tower type solar energy thermal power generation heliostat monolithic devices face splicing online test method, detailed process is as follows:
Installation site between S1, adjustment lattice supporting framework 1, truss fixed structure 2 and displacement transducer 3 is right in advance
The initial position for having completed the probe 315 in the displacement transducer 3 of adjustment is demarcated, and is determined to be measured by orbital path
Solar eyepiece 4 is transported at the position directly below of detection means;
The initial position of the probe 315 is:The bulb end of the bottom of probe 315 and the lower surface for the bottom plate 301 that is connected
Coplanar position;
S2, power-on, descending vertically by the driving screw of electric control system controls spindle motor 310, probe 315 is erected therewith
Directly move downward, and it is vertical descending through the bottom plate 301 that is connected, when the bulb termination of probe 315 contacts corresponding unit
During mirror upper surface, due to the stop of unit mirror, probe 315 will stop moving downward, and now the screw of spindle motor 310 is run to down
Extreme position stops;
When S3, the unit mirror being measured by the acquisition contact of probe 315 of magnetic grid ruler reading head 306, probe 315 stretches out connection
The length of the fixed lower surface of bottom plate 301, and the extension elongation of probe 315 is shown in real time in the form of numerical value over the display,
By adjusting the setting height(from bottom) per face unit under test mirror, and observe the real-time numerical value of display, it is ensured that per the installation of face unit mirror
Precision in theoretical error range, and then meet the monolithic devices face of heliostat 4 splicing on-line checking during, side install adjust frontier inspection
The demand of survey;
When S4, the installation of the heliostat 4 and adjustment reach theory calls, then detection is completed, and then passes through electric-control system
Control spindle motor 310 to drive screw up vertically, stop when screw drives probe 315 to run at upper extreme position, even
The probe fixed block 308 for connecing probe 315 will be equal by whole probes 315 in the free support of screw connecting plate 313, device to be detected
After moving at upper extreme position, the heliostat 4 completed will be detected by orbital path and be transported to designated area, then next group is treated
Measure solar eyepiece 4, which is transported at the position directly below of detection means, to be debug, and it is whole that repeat the above steps S2, S3 complete heliostat 4
Splice on-line checking process in build face.
Claims (8)
1. on-line measuring device is spliced in tower type solar energy thermal power generation heliostat monolithic devices face, it is characterised in that:
The detection means is made up of lattice supporting framework (1), truss fixed structure (2) and displacement transducer (3), the truss
Supporting construction (1) is fixed on ground runners in couples, and the truss fixed structure (2) is across in a pair of lattice supporting frameworks
(1) top, truss fixed structure (2) the two ends bottom forms one group of dragon with being fixedly connected at the top of lattice supporting framework (1)
Portal-framed structure;
Institute's displacement sensors (3) are vertically installed at truss fixed structure (2) both sides, every two pairs of displacement transducers (3) in couples
For one group, multigroup displacement transducer (3) is horizontally installed with each truss fixed structure (2);
The detection means is made up of multigroup gantry frame structure longitudinal arrangement.
2. on-line measuring device is spliced in tower type solar energy thermal power generation heliostat monolithic devices face as claimed in claim 1, its feature exists
In:
The lattice supporting framework (1) is by truss lower carrier plate (101), ribs I (102), truss upright-column (103), ribs II
(104) constituted with truss upper supporting plate (105);
The truss upright-column (103) is fixed by truss lower carrier plate (101) and ground runners, and the truss upper supporting plate (105) is solid
It is scheduled at the top of truss upright-column (103), and is connected with truss fixed structure (2), ribs I (102) is welded on truss upright-column (103)
Between truss lower carrier plate (101), the ribs II (104) be welded on truss upright-column (103) and truss upper supporting plate (105) it
Between.
3. on-line measuring device is spliced in tower type solar energy thermal power generation heliostat monolithic devices face as claimed in claim 1, its feature exists
In:
The truss fixed structure (2) is by truss crossbeam (201), crossbeam pinboard (202), fixed support frame (203) and sensing
Device connecting plate (204) is constituted.The truss crossbeam (201) is the cuboid framework being welded by shaped steel, two crossbeams
Pinboard (202) is symmetrically fixed at truss crossbeam (201) bottom surface two ends, the crossbeam pinboard (202) and lattice supporting framework
(1) it is connected, the sensor connecting plate (204) is installed on truss crossbeam (201) side by the fixed support frame (203),
The sensor connecting plate (204) is connected with displacement transducer (3).
4. on-line measuring device is spliced in tower type solar energy thermal power generation heliostat monolithic devices face as claimed in claim 1, its feature exists
In:
Institute's displacement sensors (3) are by the bottom plate that is connected (301), the plate I (302) that is connected, guide rail end cap (303), magnetic grid
Chi (304), line slideway (305), magnetic grid ruler reading head (306), slide attachment plate (307), probe fixed block (308), connection
Fixed upper plate (309), spindle motor (310), the plate II (311) that is connected, screw connecting plate (313), probe (315), leading screw
Lower end fixed block (318), linear bearing I (319) and probe baffle plate (322) composition;
The bottom plate that is connected (301), the plate I (302) that is connected, the upper plate that is connected (309) and the plate II that is connected
(311) cuboid that right angle setting composition is closed successively;
The line slideway (305) is fixed on the inside of the plate I (302) that is connected, and the guide rail end cap (303) is fixedly mounted on directly
Line guide rail (305) two ends, the magnetic railings ruler (304) be arranged in parallel with line slideway (305) and installed in the plate I that is connected
(302) on, the probe fixed block (308) is connected by slide attachment plate (307) with the sliding block of line slideway (305), described
Magnetic grid ruler reading head (306) is arranged on slide attachment plate (307) side and matched with magnetic railings ruler (304);
The probe (315) is connected to below probe fixed block (308) vertically, spindle motor (310) company of being vertically installed at
Connect on fixed upper plate (309), the probe fixed block (308) passes through screw connecting plate (313) and the screw of spindle motor (310)
It is connected, leading screw lower end fixed block (318) is fixed on the leading screw end of spindle motor (310), coordinates with leading screw tip gap;
The linear bearing I (319) is arranged on the bottom plate that is connected (301) immediately below probe (315), the probe baffle plate
(322) it is slidably mounted on the bottom plate that is connected (301) bottom, and on the probe baffle plate (322) at linear bearing I (319) axis hole
The upper surface on surface and the bottom plate that is connected (301) is coplanar.
5. on-line measuring device is spliced in tower type solar energy thermal power generation heliostat monolithic devices face as claimed in claim 4, its feature exists
In:
Institute's displacement sensors (3) also include linear bearing II (312), the axis of guide (314) and axis of guide fixed block (317);
The axis of guide (314) is arranged on the leading screw both sides of spindle motor (310) by axis of guide fixed block (317), described straight
Bobbin holds II (312) and is slidably connected on the axis of guide (314), and is connected with screw connecting plate (313).
6. on-line measuring device is spliced in tower type solar energy thermal power generation heliostat monolithic devices face as claimed in claim 4, its feature exists
In:
Institute's displacement sensors (3) also include the free end-stopping plate (320) for being fixed on the bottom plate that is connected (301) bottom surface and fixed
End-stopping plate (321), the probe baffle plate (322) is slidably mounted on the groove in free end-stopping plate (320) and fixed end-stopping plate (321)
Interior, when pushing the probe baffle plate (22) in fixed end-stopping plate (21) groove to free end-stopping plate (20), probe baffle plate (22) is by straight line
The axis hole of bearing I (19) is blocked, when probe baffle plate (22) is forced back towards in fixed end-stopping plate (21) groove, linear bearing I (19)
Axis hole it is exposed.
7. on-line measuring device is spliced in tower type solar energy thermal power generation heliostat monolithic devices face as claimed in claim 4, its feature exists
In:
The leading screw of the spindle motor (310) is trapezoidal screw.
8. online test method is spliced in tower type solar energy thermal power generation heliostat monolithic devices face, it is characterised in that:
The detection method detailed process is as follows:
Installation site between S1, adjustment lattice supporting framework (1), truss fixed structure (2) and displacement transducer (3), in advance
The initial position of the probe (315) in displacement transducer (3) to having completed adjustment is demarcated, will be to be measured by orbital path
The heliostat (4) of amount is transported at the position directly below of detection means;
The initial position of the probe (315) is:When the lower surface of probe (315) end and the bottom plate (301) that is connected is coplanar
Position;
S2, power-on, descending vertically by electric control system controls spindle motor (310) driving screw, probe (315) is erected therewith
Directly move downward, and it is vertical descending through the bottom plate (301) that is connected, when probe (315) end touches the corresponding settled date
During mirror (4) upper surface, probe (315) will stop moving downward, and now spindle motor (310) screw is run at lower limit position
Stop;
When S3, heliostat (4) being measured by magnetic grid ruler reading head (306) acquisition probe (315) contact, probe (315) is stretched
Go out the length of the bottom plate that is connected (301) lower surface, and by the extension elongation of probe (315) over the display in the form of numerical value
Display in real time, by the setting height(from bottom) of the tested heliostat (4) of adjustment, and observes the real-time numerical value of display, it is ensured that heliostat (4)
Installation accuracy in theoretical error range, and then meet heliostat (4) monolithic devices face splicing on-line checking during, Bian An
Debug the demand of frontier inspection survey;
When S4, the installation of the heliostat (4) and adjustment reach theory calls, then detection is completed, and then passes through electric-control system control
Spindle motor (310) processed drives screw up vertically, stops when screw drives probe (315) to run at upper extreme position,
After whole probes (315) in device to be detected are moved at upper extreme position, it will detect that the heliostat (4) completed passes through track
Delivery pathways are to designated area, then next group of heliostat (4) to be measured is transported at the position directly below of detection means enters luggage
Adjust, repeat the above steps S2, S3 complete heliostat (4) monolithic devices face splicing on-line checking process.
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CN112104315A (en) * | 2020-09-17 | 2020-12-18 | 广州一讯科技有限公司 | Photovoltaic power generation equipment roof fixed bolster |
CN113510880A (en) * | 2021-03-31 | 2021-10-19 | 洛阳双瑞风电叶片有限公司 | Intelligent control system and control method for wind power blade mould airfoil profile |
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